Exoplanets with the James Webb Space Telescope T. Greene, NASA Ames Research Center in collaboration with T. Barman, C. Beichman, M. Clampin, D. Deming, J. Fortney, M. Marley 24 July 2009
Exoplanet Landscape in 2014 JWST Launch Likely over 750 RV exoplanets known HARPS-N, APF, IR RV(?), other facilities online Maybe some ~1M Earth planets around M dwarfs (~1-4 m/s; IR) Perhaps >100 bright transiting planets with RV Spitzer warm IRAC & HST (WFC3 / STIS / NICMOS) will have observed all bright transiting planets known as of 2010+ Kepler & Corot surveys complete: planet number & size statistics Perhaps > 1000 new exoplanets over 100 sq deq FOV; most 12 < V < 15 (Johnson mags), short period, gas giants; > 100 small ones? Super-Earths in habitable zones around M dwarfs may be discovered by ground-based transit surveys (e.g., Charbonneau Mearth) Many transiting planets around bright stars (accessible via RV) could be found if a small dedicated space mission has flown (too bad re. TESS) Ground-based searches limited to ~0.5% depths and short periods Some information about exozodiacal dust from Keck & LBT-I Numerous large planets imaged from ground (GPI) 24 July 2009 JWST Exoplanet Observations 2
JWST in a nutshell 6.5-m primary mirror; 18 segments λ ~1-28 µm Instruments: NIRCam NIRSpec MIRI (cam + spec) FGS w/tf & NRM 2014 launch Arianne V to L2 5 yr req life 10 yr goal No cryogens 24 July 2009 JWST Exoplanet Observations 3
JWST Transit Capabilities: Instruments (2) NIRCam: 1 5 µm images & some spectra Images over 0.7 5 µm Nyquist sampled at 2 and 4 µm R ~ 1700 spectra 3 5 µm (not continuous) K ~ 5-8 bright limit via subarrays, weak lenses, spectra NIRSpec: 1 5 µm spectra R=100 (1 setting) and R=2700 (3 settings) spectroscopy with coarse (100 mas) spatial sampling for single or multiple objects Implementing a very wide slit (1.6 arcsec) to eliminate slit modulation MIRI: 5 28 µm images & spectra 5 28 µm Imager Nyquist sampled at 7 µm Low Res Spectrograph R~100 λ = 5 10 (14) µm Med Res R=3000 Integral Field image slicer spectrograph Fine Guidance Sensor Tunable Filter (FGS TFI) 1 5 µm images @ R~100 Has a non-redundant mask interferometer 24 July 2009 JWST Exoplanet Observations 4
NIRCam Coronagraphic Masks & TFI NRM NIRCam Coronagraph Masks TFI Non-redundant (pupil) mask interferometer apertures (Sivaramakrishnan et al. 2009) 24 July 2009 JWST Exoplanet Observations 5
JWST/NIRCAM CORONAGRAPHIC CONTRASTS Raw Rolled Krist et al 2007 (SPIE) r = 0.6 r =1.2 24 July 2009 JWST Exoplanet Observations 6 WITH PSF SUBRACTION W/O PSF SUBTRACTION
NIRCam & TFI planet imaging detectability NIRCam TFI NRM all Beichman et al. 2009 24 July 2009 JWST Exoplanet Observations 7
Transit & Eclipse Geometries Transit T. Brown & L. Allen 24 July 2009 JWST Exoplanet Observations 8
Exoplanet transit observations 2008/9 2008 HD 189733b IRAC 8µm photometry Knutson et al. 2007 No core 20Me core CoRoT-7b Over 50 exoplanets characterized via both transits and RV (only 11 in 2007); numerous Spitzer secondary eclipse observations) About half are ~ Jovian mass & size 24 July 2009 JWST Exoplanet Observations 9
JWST Transit Capabilities (1) How much better will JWST be than Spitzer or Hubble that are producing such great results today? Two major improvements Larger aperture has more area (25 vs 0.5 m^2) for collecting light - about 7x the effective diameter of Spitzer: S/N should be 7x more than Spiter in same time 50 x less integration time for Spitzer S/N We are still modifying the instruments to optimize them for transit observations! Better near- and mid-ir capabilities overall Reduce / eliminate slit losses in spectrographs Studying spect. precision limits (Clampin, Deming, Lindler) Optimize operation & calibration strategies (precision, bright limits) 24 July 2009 JWST Exoplanet Observations 10
Simulation: HD 189733b should be great! H2O (+CH4) H2O (+CH4) Primary transit simulation Using T=1250K model from J. Fortney (10 hr ) 24 July 2009 JWST Exoplanet Observations 11
GJ 436b will be tough! (small & cold) H2O (+CH4)? Transit simulation using J. Fortney 1X solar model (20 hr) 24 July 2009 JWST Exoplanet Observations 12
HD 189733b nir Sec. Eclipse H2O + CH4 abs H2O + CO abs 24 July 2009 JWST Exoplanet Observations 13
HD189733b MIRI LRS R=100 simulation H2O CH4 t = 4 hr total 24 July 2009 JWST Exoplanet Observations 14
MIRI detection of CO 2 abs. in Super-Earths Deming et al. (2009) showing Miller-Ricci Super-Earth (2009) and MIRI filters JWST MIRI filters (red boxes, left) can be used to detect deep CO2 absorption in Super-Earth atmospheres (Miller- Ricci 2009 model, left) Modelling shows that modest S/N detections possible on several M star planets (Deming et al. 2009). 24 July 2009 JWST Exoplanet Observations 15
JWST Exoplanet Summary NIRCam and TFI/NRM can image / characterize planets with a wide range of masses and separations JWST will characterize hot giant planets with high S/N and at R=100 500 spectral resolution with near-ir and mid-ir transit and secondary eclipse observations Planet features detectable in a single transit @ R=500! Thermal emission from super-earth transiting planets in habitable zones of M stars can be detected in a few transits in a broad-band 20 µm filter Characterization of some small planet atmsopheres possible Exotic Super Earths (low gravity, H dominated atmospheres) possible! Atmospheres of strict Earth analogs cannot be characterized Stars produce too much photon noise 24 July 2009 JWST Exoplanet Observations 16